To cite the freealg package in publications, please use
Hankin (2022b). In this short document I
show how free algebras may be studied using the freealg
package. The free algebra is best introduced by an example:
with an alphabet of \(\{x,y,z\}\), and
real numbers \(\alpha,\beta,\gamma\) we
formally define \(A=\alpha x^2yx + \beta
zy\) and \(B=-\beta zy + \gamma
y^4\). Addition is commutative so \(A+B=B+A\). However, multiplication is not
commutative so \(AB\neq BA\) in
general; both are associative. We also have consistency in that \(\alpha(\beta P)=(\alpha\beta)P\) for any
expression \(P\). Then:
\[ A+B=(\alpha x^2yx + \beta zy) + (-\beta zy + \gamma y^4) = \alpha x^2yx + \gamma y^4 \]
\[ AB= (\alpha x^2yx + \beta zy) (-\beta zy + \gamma y^4) = -\alpha\beta x^2yxzy +\alpha\gamma x^2yxy^4 -\beta^2zyzy +\beta\gamma zy^5 \]
\[ BA=(-\beta zy + \gamma y^4)(\alpha x^2yx + \beta zy) = -\alpha\beta zyx^2yx -\beta^2 zyzy + \alpha\gamma y^4x^2yx + \beta\gamma y^4zy \]
This is a natural set of objects to consider. Formally, we consider the free R-module with a basis consisting of all words over an alphabet of symbols [conventionally lower-case letters] with multiplication of words defined as concatenation. The system inherits associativity from associativity of concatenation; distributivity follows from the definition of R-module. However, the free algebra is not commutative in general.
freealg package in useThe above examples are a little too general for the
freealg package; the idiom requires that we have specific
numerical values for the coefficients \(\alpha,\beta,\gamma\). Here we will use
\(1,2,3\) respectively.
## free algebra element algebraically equal to
## + xxyx + 2zy## free algebra element algebraically equal to
## + 3yyyy - 2zy## free algebra element algebraically equal to
## + xxyx + 3yyyy## free algebra element algebraically equal to
## + 3xxyxyyyy - 2xxyxzy + 6zyyyyy - 4zyzy## free algebra element algebraically equal to
## + 3yyyyxxyx + 6yyyyzy - 2zyxxyx - 4zyzyNote that the terms are stored in an implementation-specific order.
For example, A might appear as xxyz + 2*zy or
the algebraically equivalent form 2*zy + xxyz. The package
follows disordR discipline (Hankin
2022a).
Inverses are coded using upper-case letters.
## free algebra element algebraically equal to
## + xxy + 2zyXSee how multiplying by \(X=x^{-1}\)
on the right cancels one of the x terms in A.
We can use this device in more complicated examples:
## free algebra element algebraically equal to
## + 3 + 5X - 2Xyx## free algebra element algebraically equal to
## + 5xxy + 3xxyx - 2xxyyx + 6zy + 10zyX - 4zyXyx## free algebra element algebraically equal to
## - 2Xyxxxyx - 4Xyxzy + 10Xzy + 3xxyx + 5xyx + 6zyWith these objects we may verify that the distributive and associative laws are true:
## [1] TRUE## [1] TRUE## [1] TRUEVarious utilities are included in the package. For example, the commutator bracket is represented by reasonably concise idiom:
## free algebra element algebraically equal to
## + ab - baUsing rfalg() to generate random free algebra objects,
we may verify the Jacobi identity:
## free algebra element algebraically equal to
## 0The package includes functionality for substitution:
## free algebra element algebraically equal to
## + aaccc + 3aaxccc## free algebra element algebraically equal to
## + 4accc + 3adccc + 6aecccIt is possible to extract components of freealg objects
using reasonably standard idiom:
## free algebra element algebraically equal to
## + aaa + 2aaba + 3abbbba - 3abc + 9xyzabc## free algebra element algebraically equal to
## + 3abbbba + 9xyzabc## free algebra element algebraically equal to
## + aaa + 2aaba + 3abbbba + 99abc + 9xyzabcThere is even some experimental functionality for calculus:
## free algebra element algebraically equal to
## + aaaxa(da) + aaax(da)a + aa(da)xaa + a(da)axaa + (da)aaxaaAbove, “da” means the differential of a.
Note how it may appear at any position in the product, not just the end
(cf matrix differentiation).
disordR Package.”
arXiv. https://doi.org/10.48550/ARXIV.2210.03856.